Control of bacteriophage lambda CII activity by bacteriophage and host functions

We have studied the regulation of the lambda cII gene in vivo using cloned lambda fragments. Lambda N protein stimulated cII expression. Surprisingly, although very high cII protein levels were detected by gel electrophoresis, little cII protein activity, measured as stimulation of the lambda pI and pE promoters, was observed. The half-life of cII protein depended critically on its initial level. At low concentrations its half-life was as short as 1.5 min, whereas at high cII protein levels, it could be as long as 22 min. The Escherichia coli mutant ER437 directs lambda towards lysogeny; cII protein was more stable in this strain than in the wild type. On the other hand, although cyclic AMP is required for efficient lysogeny, it did not appear to influence the synthesis, stability, or activity of cII protein.     

Infection of transformable cells ofHaemophilus influenzae by bacteriophage and bacteriophage DNA

Summary A phage HP1, infecting transformable cells ofHaemophilus influenzae Rd, has been isolated. The general properties of the wild type and of a clear plaquemutantc1 employed for most of the experiments are described. Phage DNA is infective for transformableHaemophilus cells with an efficiency (plaqueforming units of the original phage recovered as DNA-infected cells) of up to 6×10^–3. The competence ofHaemophilus cells for infection with phage DNA parallels the competence for transformation with bacterial DNA.Both HP1 and thec1 mutant are able to lysogenize their host, and the lysogenic cells are readily induced by UV. Competent non-lysogenicHaemophilus cells can be infected by DNA of lysogenic cells, thereby giving rise to phage progeny. Thus, the phage genetic material can be introduced into competentHaemophilus cells in three different ways: injection from intact phage, and infection with either phage DNA or with bacterial DNA carrying the prophage.The UV inactivation curves for infectious phage DNA and for complete phages are similar, both indicating the occurrance of host-cell reactivation. Photoreactivationin vitro of infectious phage DNA takes place to about the same high extent as observed with bacterial transforming DNA.The usefulness of this system for investigating bacterial transformation and biological effects ofin vitro treatment of DNA is discussed.with the technical assistance ofSandra J. Antoine With 4 Figures in the TextPreliminary report presented at the 7th Annual Bacterial Transformation Meeting, Aspen, Colorado, June 17–19, 1963.Supported by a travel grant from the Deutsche Forschungsgemeinschaft.Supported by Research Carreer Development Award GM-K3-7500 and Research Grant RH 00221 from the U.S. Public Health Service.     

Transduction of bacteriophage lambda by bacteriophage T1.

When bacteriophage T1 was grown on bacteriophage lambda-lysogenic cells, phenotypically mixed particles were formed which had the serum sensitivity, host range, and density of T1 but which gave rise to lambda phage. T1 packaged lambda genomes more efficiently both when the length of the prophage was less than that of wild-type lambda and when the host cell was polylysogenic. Expression of the red genes of lambda or the recE system of Escherichia coli during T1 growth enhanced pickup of lambda by T1, whereas packaging was reduced in recB cells. If donors were singly lysogenic, the expression of transduced lambda genomes as a PFU required lambda-specified excisive recombination, whereas lambda genomes transduced from polylysogens required only lambda- or E. coli-specified general recombination to give a productive infection.     

Transduction of bacteriophage Mu by bacteriophage T1.

Phage T1 transduces phage Mu PFU from Mu-lysogenic donor cells to sensitive recipient cells. The efficiency of transduction depends on the chromosomal location of the Mu prophage. T1, therefore, appears to package different regions of the bacterial chromosome with different efficiencies. Although T1 transduces bacterial markers with different efficiencies, there is no direct correlation between the efficiency of transduction of a bacterial marker and the efficiency of transduction of Mu PFU from donor cells with the Mu prophage located in that marker.     

Vibrio cholerae bacteriophage CP-T1: characterization of bacteriophage DNA and restriction analysis

Temperature bacteriophage CP-T1 of Vibrio cholerae has a capsid that is 45 nm in diameter, a contractile tail 65 nm long and 9.5 nm wide, and a baseplate with several spikes or short tail fibers. The linear double-stranded DNA is 43.5 +/- 1.4 kilobases long, and the phage genome is both terminally redundant and partially circularly permuted. The extent of terminal redundancy is ca. 4%, and circular permutation is up to ca. 44%. Circular restriction maps have been constructed for the enzymes HindIII, EcoRI, BamHI, and PstI. By restriction endonuclease and heteroduplex analyses of phage DNA, the presence and location of a site (pac) at which packaging of phage DNA is initiated was established.     

DNA modification of bacteriophage Mu-1 requires both host and bacteriophage functions.

It was previously shown that resistance of phage Mu-1 to several restriction enzymes is due to a modification function (called mom) encoded by the phage. More recent studies emphasized that modification of Mu requires not only an active mom function, but also an active dam function supplied by the Escherichia coli host.     

Assembly of bacteriophage T7. Dimensions of the bacteriophage and its capsids.

The dimensions of bacteriophage T7 and T7 capsids have been investigated by small-angle x-ray scattering. Phage T7 behaves like a sphere of uniform density with an outer radius of 301 +/- 2 A (excluding the phage tail) and a calculated volume for protein plus nucleic acid of 1.14 +/- 0.05 x 10(-16) ml. The outer radius determined for T7 phage in solution is approximately 30% greater than the radius measured from electron micrographs, which indicates that considerable shrinkage occurs during preparation for electron microscopy. Capsids that have a phagelike envelope and do not contain DNA were obtained from lysates of T7-infected Escherichia coli (capsid II) and by separating the capsid component of T7 phage from the phage DNA by means of temperature shock (capsid IV). In both cases the peak protein density is at a radius of 275 A; the outer radius is 286 +/- 4 A, approximately 5% smaller than the envelope of T7 phage. The thickness of the envelope of capsid II is 22 +/- 4 A, consistent with the thickness of protein estimated to be 23 +/- 5 A in whole T7 phage, as seen on electron micrographs in which the internal DNA is positively stained. The volume in T7 phage available to package DNA is estimated to be 9.2 +/- 0.4 x 10(-17) ml. The packaged DNA adopts a regular packing with 23.6 A interplanar spacing between, DNA strands. The angular width of the 23.6 A reflection shows that the mean DNA-DNA spacing throughout the phage head is 27.5 +/- less than 2.2 A. A T7 precursor capsid (capsid I) expands when pelleted for x-ray scattering in the ultracentrifuge to essentially the same outer dimensions as for capsids II and IV. This expansion of capsid I can be prevented by fixing with glutaraldehyde; fixed capsid I has peak density at a radius of 247 A, 10% less than capsid II or IV.     

Competition between bacteriophage f2 RNA and bacteriophage T4 messenger RNA

In an $\text{Escherichia coli}$ cell-free protein synthesis assay, mRNA isolated from cells late after infection by phage T4 out-competes bacteriophage f2 RNA. Addition of a saturating or subsaturating amount of T4 mRNA inhibits translation of f2 RNA, while even an excess of f2 RNA has no effect on translation of T4 mRNA. Peptide mapping of reaction products labeled with formyl-[³⁵S]-methionyl-tRNA was used to quantitate f2 and T4 protein products synthesized in the same reaction. We suggest that messenger RNA competition might be one mechanism by which T4 superinfection of cells infected with phage f2 blocks translation of f2 RNA and possibly host mRNA.     

合成噬菌体的贡献与风险

噬菌体（bacteriophage,phage）是感染细菌、真菌、放线菌或螺旋体等微生物的细菌病毒的总称。噬菌体在生态、微生物进化、细菌性疾病预防和治疗、细菌鉴定与疾病诊断等方面扮演重要角色。基因组测序技术和高效合成平台促进了合成基因组学的发展。利用合成基因组学技术,对噬菌体基因组进行设计或者合成出新的噬菌体来服务人类在不久的未来可能成为现实。但与此同时,合成噬菌体带来的风险也必须认真考虑。     

Studies on bacteriophage distribution: virulent and temperate bacteriophage content of mammalian feces.

Freshly voided samples of the feces of cows, pigs, and humans were analyzed for the enumeration of cell-free plaque-forming units (PFU) of coliphages and Salmonella phages. Coliphage PFU counts per gram (wet weight) of feces were found to range from less than 10(1) to greater than 10(7). Salmonella phages were found in three out of five porcine samples, but none were found in the four bovine samples analyzed. Virulent coliphages related to the phiX174/S13 serological group showed some "habitat preference" in that the S13 type of phages was found only in pig feces, whereas the phiX174 type of phages was found only in cow dung. Temperate coliphages were detectable in a majority of samples of both human and porcine origin but were infrequently found in bovine samples. About 80% of the temperate coliphages of fecal origin have been found to be serologically related to phage HK022 (Dhillon and Dhillon, 1973), and all are efficiently inducible by ultraviolet light irradiation. However, considerable diversity with the group was found when the prophage immunity pattern of 10 randomly selected isolates was examined.